KR20180082620A - Bellows restraining device - Google Patents

Abstract

The bellows constraining device includes a first bracket having a first mount and a first arm extending from the first mount, a second mount extending from the second mount to the first arm and having at least one through hole And a first fastener extending from the second mount to the first mount and connected to the first arm through at least one through hole of the second arm, Has a cross-sectional area smaller than the cross-sectional area of the at least one through-hole, such that the first bracket is movable relative to the second bracket.

Description

Bellows restraining device

This application claims priority to U.S. Provisional Application No. 62 / 263,890 entitled " Hydraulic System Bellows Restraint ", filed December 7, 2015, the disclosure of which is incorporated by reference in its entirety. This application also claims priority to U.S. Patent Application No. 15 / 082,317, entitled "Bellows Restraint," filed March 28, 2016, the disclosure of which is incorporated by reference in its entirety.

The present invention relates to a bellows used in a hydraulic system, and more particularly to a bellows restraint used with a bellows existing along a hydraulic fluid line.

The bellows, known as expansion joints, are located along the hydraulic line and are used to stretch, compress and deflect the hydraulic line without damaging the rigid hydraulic line. A bellows restraining device may be installed to enclose the bellows to prevent damage due to excessive elongation, compression and transverse deflection.

The bellows restraint devices generally include a cylindrical tube surrounding the bellows to prevent excessive wrapping of the bellows and a rod moving parallel to the bellows on each side. These bellows restrictors take up a lot of space and can not be installed on existing bellows, and they must be designed and integrated for the newly designed bellows. Further, the bellows restraining devices can not be easily adjusted after the bellows restraining device is mounted around the bellows.

The bellows constraining device includes a first bracket having a first arm and a first arm extending from the first mount, a second bracket extending from the second mount and the second mount adjacent to the first arm and having at least one through- A second bracket having an arm and a first fastener extending to be connected to the first arm through the at least one through hole of the second arm. The first fastener may have a cross sectional area smaller than the cross sectional area of the at least one through hole so that the first bracket can be interlocked with the second bracket.

An expansion joint having a restraint device includes a tube having a hollow inner flow passage configured to allow fluid to flow through the tube, an expansion joint existing along the tube, a male mount abutting the tube, An arm bracket including a male bracket having a male arm, an arm mount abutting the tube, and a female arm extending adjacent to the expansion joint and the male arm and having at least one through hole, and the at least one And a first standoff extending through the through-hole of the expansion joint and fastened to the male arm configured to limit elongation, compression and angular deflection of the expansion joint.

The connecting portion along the hydraulic fluid pathway includes a fluid line; A bellows along a fluid line configured to permit compression, extension and angular deflection of the fluid line; And a bellows constraining device adjacent the bellows configured to limit compression, extension and deflection of the fluid line.

The bellows constraining device including a first support having a first bellows attachment portion for connecting a first support to a first end of the bellows and a first extension extending along a fluid line adjacent the bellows; And a second support having a second bellows attachment portion, a second extension, a first bore and a second bore, the second bellows attachment portion connecting the second support to a second end surface of the bellows, And extends along the fluid line adjacent the first extension and adjacent the bellows. Wherein the first shaft includes a first standoff having a first shaft and a first head, the first shaft extending through a first hole in the second extension and connected to the first extension, Sectional area smaller than the cross-sectional area. And a second standoff having a second shaft and a second head, the second shaft extending through a second hole in the second extension to connect to the first extension and the second shaft having a cross- And has a smaller cross-sectional area.

1 is a partial perspective view of a hydraulic system.
2A is a perspective view of a bellows restraining device in a free state.
Figure 2b is a partial cross-sectional view of the bellows restraining device of Figure 2a.
2C is a partial perspective sectional view of the bellows restraining device of Fig.
Figure 3a is a side view of the bellows restraint device in an extended state.
3B is a side view of the bellows restrictor in the compressed state.
3C is a side view of the bellows restraining device in the first deflected state.
Figure 3d is a partial cross-sectional top view of the bellows confinement device in a second deflected state.
4 is a front cross-sectional view of the male bracket of the bellows restraint device.
5 is a front sectional view of the arm bracket of the bellows restraint device.
6 is a front view of the standoff of the bellows restraining device.
7 is a measurement view of another embodiment of the standoff used in the bellows restraint device in the first deflection state.
8 is a side view of a third embodiment of the standoff used in the bellows restraint device in the first deflection state.
9 is a perspective view of a fourth embodiment of a bellows restraining device in a free state.

While the above drawings illustrate one embodiment of the present invention, they are also included in other embodiments as mentioned above. In all cases, the above description is exemplified by the exemplary method of the present invention and is not limited. It is to be understood that many other modifications and embodiments within the spirit and scope of the principles of the present invention may be invented by those skilled in the art. The drawings may not be drawn to scale and the applications and embodiments of the invention may include features and elements not specifically shown in the figures.

A bellows restraint device for use with a bellows includes a male and a female bracket extending from opposite ends of the bellows toward each other to limit elongation, compression and angular deflection of the bellows. The bellows may be along a line of fluid that carries fluid, such as a tube or hydraulic system. The male bracket has a mount coupled to the tube adjacent to the bellows and an arm extending adjacent the bellows. The arm bracket also has a mount coupled to the tube at the opposite end of the bellows and an arm extending adjacent to the bellows and adjacent to the arm of the male bracket. The bellows restraint device includes at least one standoff extending through the through hole corresponding to the arm of the female bracket for connection to the male bracket at the corresponding connection point. Before the standoff is touched to the arm of the arm bracket (the side of the through hole) to prevent excessive movement of the bellows, the standoff and the through hole are sized to allow a certain amount of extension, compression and angular deflection of the bellows.

The disclosed bellows restrictor has many advantages. The bellows restrictor may also be used when the bellows and tube are coated with a corrosion resistant coating. With the coating, the bellows can stretch, compress and deflect only a certain amount of time before the coating cracks occur, so the bellows restrictor limits the movement of the bellows to prevent damage to the coating.

The bellows restraining device can prolong the life of the bellows by preventing damage to the bellows due to excessive extension, compression and transverse deflection. The bellows restrictor may be configured to limit a specific amount to the bellows.

For example, some bellows restraints can be designed to allow 5% movement in all directions while another bellows restraint can be designed to allow 10% angular deflection and 7% stretch and compression. The bellows restraint is simple enough to require only two contact points (on the male and female bracket mounts) and a limited number of components.

As described above, the bellows-restraining device may have a standoff of a non-circular cross-section, large or small in diameter; For example, elliptical, rectangular, triangular or other shapes; Or to be somewhat restrained by replacing it with another long or short standoff.

In addition, the arm bracket can be replaced with another arm bracket having an arm having a through hole of a different size, so that the movement of the standoff in the through hole can be facilitated somewhat.

Another advantage is that the bellows restraining device is smaller in size than the prior art bellows restraining devices and conventionally has a cylindrical tube surrounding the bellows with rods extending parallel to the bellows on each side to prevent the bellows from performing extensive motion Whereas the disclosed bellows restraint device has arms of a male bracket and an arm of a female bracket and extends along one side of the bellows and restricts the movement of the bellows in all directions.

Finally, the bellows restrictor can be coupled to an existing bellows without the need to modify or replace the bellows or other components of the overall system. Each of these advantages, along with others, will be appreciated in the following examples.

1 is a partial perspective view of a hydraulic system. The hydraulic system 10 includes a wall 12, a tube 14 (also referred to as a 'fluid line'), a bellows 16 (also referred to as an expansion joint), a bellows constraining device 18 and a joint 20. The hydraulic system 10 may be located along a flow path connecting two components in any type of system, such as a system in the semiconductor industry. While the hydraulic fluid is used to describe the fluid flowing through the flow path, the disclosed bellows 16 and bellows restraining device 18 may be used with any fluid as well as a hydraulic fluid.

The hydraulic fluid enters one end of the tube 14 and flows through the tube 14 (and through the bellows 16 and joint 20) and into the other end of the tube 14. The components of the hydraulic system 10 may be comprised of a variety of materials including stainless steel, composite materials, plastics, combinations thereof, or other materials. The hydraulic system 10 may also include a plurality of resilient seals to ensure that the passages are fluidly sealed and that the hydraulic fluid can not escape to components connected to the tube 14 or tube 14 .

The components of the hydraulic system 10 can be one continuous integral component or multiple components fixed together. Each component of the hydraulic system 10 can be sized to provide sufficient strength and rigidity and is small enough to facilitate the installation of the hydraulic system 10 as an entire or separate component of the hydraulic system 10. In addition, when determining the size, shape, and constituent material of the hydraulic system 10, thermal expansion and contraction must be considered because the hydraulic fluid passing through the hydraulic system 10 can flow at high or low temperatures.

The wall 12 of the hydraulic system 10 represents a component adjacent to the tube 14, the bellows 16 and the bellows restraining device 18, and the bellows 16 may extend, compress and / The tube 14 can be contacted. As described below, the bellows restraining device 18 may be configured to prevent contact between the tube 14 and the wall 12, as such contact may cause damage to the tube 14. However, the bellows constraining device 18 may be configured to allow some movement of the tube 14 such that the hydraulic system 10 is not rigid enough to withstand minimal movement.

The tube 14 connects between the two components of the hydraulic system 10 and forms a flow path for the hydraulic fluid. The tube 14 may have a variety of sizes and configurations to effectively and efficiently deliver the hydraulic fluid through the hydraulic system 10, and may be a number of components fastened together to facilitate construction and installation. The tube 14 can be fabricated from a variety of materials, but is preferably made of materials resistant to discoloration and rust, such as stainless steel. The tube 14 may be coated with an anti-corrosion coating or other coating along with the other components of the hydraulic system 10. The joint 20 is located along the tube 14 and is configured to change the direction of the tube 14 or to divide the flow path into a plurality of flow paths. The tube 14 may have a plurality of joints 20 along the flow path or may be constructed of a material that does not require a separate component to change direction, such as rubber or other elastic material.

The bellows 16 and the bellows constraining device 18 are located along the tube 14. Since the tube 14 is generally constructed of a rigid material such as stainless steel, the bellows 16 can be stretched, compressed and deflected as needed without damaging the tube 14. [ The bellows 16 forms a flow path between two portions of the tube 14 such that the flow path through the bellows 16 coincides with the flow path through the tube 14. [ The bellows 16 may be fabricated in a variety of ways, such as by hydroming, and may be fabricated from a variety of materials. However, the bellows 16 should be made of a material that can be stretched, compressed and deflected without being damaged. In addition, the internal flow path of the tube 14 may be coated with an anti-corrosion coating or other coating. The bellows 16 may be sized and shaped to allow the hydraulic fluid to effectively flow through the flow path while allowing the tube 14 to be stretched, compressed and deflected. Those skilled in the art are familiar with the structure and function of the bellows 16.

The bellows constraining device 18 is adjacent the bellows 16 along the tube 14. The bellows constraining device 18 prevents damage to the bellows 16 due to tube damage or the like that may occur due to excessive elongation, excessive compression and deflection of the bellows 16, or contact with other components such as the wall 12 . The bellows constraining device 18 allows the tube 14 to be connected to other components. Because, if the tube 14 moves excessively, the tube 14 may be separated from other components and hydraulic fluid may leak from the flow path. The bellows constraining device 18 may be made of a variety of materials such as stainless steel and must be a material that is rigid, intact, and strong enough not to move the bellows 16 excessively. The bellows 16 and the bellows constraining device 18 can be located anywhere along the tube 14. Depending on design considerations, the bellows 16 and the bellows constraining device 18 may be shorter than the entire length of the tube 14 or the tube 14.

2A is a perspective view of the bellows in a free state (un-stretched, uncompressed, non-deflected state). Fig. 2b is a partial cross-sectional view of the bellows-restraining device of Fig. 2a, and Fig. 2c is a partial perspective view of the bellows locker of Fig. 2a.

Figures 2a, 2b and 2c show a portion of the tube 14 with the bellows 16 and the bellows restraint 18 along the tube 14.

The bellows restraining device 18 is provided with a male bracket 24 (also referred to as a "second bracket" or a "second support"), a first bracket (also referred to as a first bracket) Off 26 (also referred to as a "first fastener") and a second standoff 28 (also referred to as a "second fastener"). The male bracket 22 includes a male mount 30 (also referred to as a first mount or a first bellows attaching portion) and a male arm 32 (also referred to as a first arm or a first extension) And the male arm 32 includes a first connector 34 (also referred to as a "threaded portion" or "hole") and a second connector 36 (also referred to as a "threaded portion" or "hole"). The arm bracket 24 includes an arm mount 40 (also referred to as a "second mount" or "second bellows attaching portion") and a female arm 32 (also referred to as a "second arm" And the female arm 32 includes a first through hole 44 (also referred to as a first opening) and a second through hole 46 (also referred to as a second opening).

The male bracket 22 is connected to the tube 14 near the end of the bellows 16 by a male mount 30, as shown in the front section of Fig. The male arm 32 is radially outwardly located at the male mount 30 and extends radially outwardly adjacent to the bellows 16. [ The male bracket 22 may be constructed from a variety of materials, such as stainless steel, and is made of materials or materials having sufficient strength to prevent excessive flow of the bellows 16 without damage and defects. The parts of the male bracket 22 may be one continuous integral part, and the male mount 30 and the male arm 32 may be discrete parts fixed to each other.

The male mount 30 is an annular shaped component that surrounds the tube 14 adjacent the end of the bellows 16. The male mount 30 is secured to the tube 14 and can be secured through various means, such as screws, bolts, screws inside the tube 30, external threads, solder, adhesive, or other means. The attachment of the male mount 30 to the tube 14 may be permanent or removable so that the male mount 30 may be replaced with another male mount having a different configuration as shown in Fig.

The connection between the male mount 30 and the tube 14 may be configured to prevent the male mount 30 from freely rotating about the tube 14 or to allow the male mount 30 to rotate around the tube 14 Lt; / RTI > The male mount 30 may be one continuous integral part including the tube 14. [ The male mount 30 may also have a different size, shape and configuration than the disclosed embodiment for connecting the male bracket 22 to the tube 14 and the male bracket 22 may be configured to receive the bellows 16 and the male mount 30 against the end of the tube 14 adjacent to it.

The male arm 32 is an extension connected at one end to the male mount 30 and at the other end to extend radially outward adjacent the bellows 16. [ The male arm 32 may be connected to the male mount 30 and extend vertically to the tangent along the male mount 30 (the female arm 42 is shown in Figures 2a, 2b, 2c) (As shown in Figures 2a, 2b, 2c) to be adjacent to the radially outer surface 42 of the plate. The male arm 32 may have a rectangular cross-sectional shape as shown and may have another cross-sectional shape depending on the design, including the required strength and the space available for the male arm 32.

The male arm 32 can be secured to the male mount 30 through various means or the male arm 32 can be one continuous and single piece with the male mount 30 mounted. The connection of the male arm 32 to the male mount 30 should have sufficient stiffness and strength to prevent excessive stretching, compression and deflection of the bellows 16 without damage or defects. The water hammer 32 is sufficiently radiative at the bellows 16 to prevent the water hammer 32 from contacting the bellows 16 when the bellows 16 is extended, Lt; RTI ID = 0.0 > 16 < / RTI > The male arm 32 may extend the entire length of the bellows 16 or may extend a shorter length than the entire length of the bellows 16. [ However, the male arm 32 should be long enough to provide sufficient space to connect to the first standoff 26 and the second standoff 28. [

The first connector 34 and the second connector 36 are spaced apart from each other along the male arm 32 and are indicated by screw holes extending all the width of the male arm 32. The first connector 34 and the second connector 36 allow the first standoff 26 and the second standoff 28 to be attached to the male arms 32, respectively. The first connector 34 and the second connector 36 may be any type of coupling to secure the first standoff 26 and the second standoff 28 to the male arm 32, The engagement which allows the second standoff 26 and the second standoff 28 to be easily separated from the male arm 32 is such that the first standoff 26 and the second standoff 28 are separated from each other by a standoff Lt; / RTI > The first connector 34 and the second connector 36 correspond to the first through hole 44 and the second through hole 46 through which the first standoff 26 and the second standoff 28 extend, Should be located along the water hammer (32).

The arm bracket 24 is shown in the front section of FIG. 5 and is connected to the tube 14 near the end of the bellows 16 so as to face the male bracket 22. The arm bracket 24 is connected to the tube by an arm mount 40. The female arm 42 extends radially outwardly from the arm mount 40 and radially outwardly adjacent the male arm 32 adjacent the bellows 16. The arm bracket 24 has a number of members constituting the male bracket 24, the number of the members constituting the male bracket 24 (i.e., the arm bracket 24 is one continuous integral part, And means for connecting the arm mount 40 to the tube 14. The male bracket 22 is preferably a metal bracket.

However, the arm bracket 24 differs from the male bracket 22 in various respects. The arm bracket 24 is connected to the tube 14 at the opposite end of the bellows 16 rather than the male bracket 22. The female arm 42 is positioned on the female mount 40 when the male arm 32 is not offset from the male mount 30 because the female arm 42 is adjacent to the male arm 32 along the bellows 16. [ (As shown in Figures 2a, 2b, 2c). In another embodiment, when the male arm 32 is radially offset from the male mount 30, the female arm 42 extends perpendicular to the tangent along the arm mount 40 (i.e., The female arm 42 will be positioned in the opposite direction in Figures 2a, 2b and 2c). The male and female arms 32 and 42 should be adjacent to each other to allow angular deflection of the bellows 16 in all directions, but not in contact with each other (as shown in FIG. 2B) I will explain in more detail.

The female arm 42 includes a first through hole 44 and a second through hole 46 extending through the female arm 42 and each through hole has a first connector 34 and a second connector 36 Of the female arm 42, respectively. The first and second standoffs 26 and 46 extend through the female arm 42 and extend through the first connector 34 and the second standoff 28. The first standoff 26 and the second standoff 28 extend through the female arm 42, 2 connector 36 to be connected to the male arms 32, respectively. The first through hole 44 and the second through hole 46 extend perpendicularly from the side surface of the female arm 42 while the first through hole 44 and the second through hole 46 are perpendicular to each other, May extend to the female arm 42 at different angles. The first through holes 44 and the second through holes 46 may have various sizes, shapes, and configurations depending on the elongation, compression, and deflection of the bellows 16 of a desired size.

One of the first standoff 26 and the second standoff 28 is shown in the perspective view of FIG. 6 and has a head 48 and a shaft 50. The first standoffs 26 extend through the first through holes 44 and the second standoffs 28 extend through the second through holes 46 such that the first and second standoffs 26, (36) to the male arm (32).

The head 48 is larger in cross-sectional area than the shaft 50 and the corresponding through-hole, and is not located in the corresponding through-hole shown in Figs. 2A, 2B and 2C. The head 48 prevents the corresponding standoff from being pushed through the through-hole, so that the male arm 32 is not separated from the female arm 42. The head 48 may also include a depression that allows the first standoff 26 and the second standoff 28 to be more easily separated from the female arm 32 by a tool such as a screwdriver. By providing a hard stop when either head 48 of either the first standoff 26 or the second standoff 28 contacts the side of the female arm 42, (To be described in more detail with respect to FIG. 3D).

The shaft 50 has a smaller cross-sectional area than the pair of heads 48 and the corresponding through-holes. In the disclosed embodiment, the shaft 50 of the first standoff 26 and the shaft 50 of the first connector 34 and the second standoff 28 and the second standoff 34 are connected to the male arm 32 by various fasteners, And shows the screwing between the shafts 50 of the second connector 36. Fig. The length and cross-sectional area of the shaft 50 should be such that the male arm 32 is allowed to move relative to the female arm 42 such that the bellows 16 can be stretched, compressed and deflected in the designed range.

The shaft 50 of each of the first standoff 26 and the second standoff 28 may have a circular cross section or other cross section; An ellipse, a rectangle, or a triangle, to allow movement of the male arm 32 in a specific range as compared with the female arm 42. The shaft 50 of the first standoff 26 and the second standoff 28 is connected to the first through hole 44, the shaft 50 of the first standoff, the second through hole 46, 2 may have various cross sections depending on the length of the shaft 50 in order to make the amount of flow of the bellows 16 vary depending on the contact between the shafts 50 of the standoffs 28. [ The first through hole 44 and the second through hole 46 may have a circular cross section or another cross section so that they function together with the respective shafts of the first standoff 26 and the second standoff 28 Thereby allowing movement of the bellows 16 in a desired range compared to other through holes having different cross-sections. The shaft 50 of each of the first standoff 26 and the second standoff 28 should have a length greater than the width of the female arm 42 because the male arm 32 is associated with the female arm 42 So that the bellows 16 can be deflected in all directions. The first connector 34, the second connector 36, the first standoff 26, the second standoff 28, the first connector 34, the second connector 36, The position of the hole 44 and the second through-hole 46 can be adjusted so as to deflect the angle of the bellows 16 more or less.

The disclosed embodiment may include two standoffs 26, 28, two connectors 34, 36, two through holes 44, 46, while another embodiment may include one or more than two each . The first stand-off 26, the second stand-off 28, the first through-hole 44, the second through-hole (not shown), and the through- 46 are all constructed in relation to one another to work together to suppress the extension, compression and deflection of the bellows 16 and also to allow for a specific range of extension, compression and angular deflection of the bellows 16. [ The first standoff 26, the second standoff 28, the first connector 34 and the second connector 36 can easily separate the first standoff 26 and the second standoff 28, So that the bellows 16 can be elongated, compressed or deflected more or less. The bellows constraining device 18 limits the expansion, compression, angular deflection of the bellows 16 in a simple and adjustable configuration and requires a limited range of components.

3B is a side view of the bellows restraining device 18 in the compressed state and FIG. 3C is a side view of the bellows restraining device 18 in the first biased state. FIG. 3A is a side view of the bellows- And Fig. 3D is a partial flat cross-sectional view of the bellows restraining device 18 in the second deflected state. Figures 3a, 3b, 3c, 3d show a portion of the bellows restraining device 18 along with the tube 14 with the bellows 16 and the tube 14. The bellows restraining device 18 includes a male bracket 22, an arm bracket 24, a first standoff 26 (having a head 48 and a shaft 50), a second standoff 28, a head 48, A male mount 30 and a female arm 32 having a first connector 34 and a second connector 36), an arm mount 40, a female arm 42 Through hole 44 and second through hole 46). Figures 3a, 3b, 3c and 3d illustrate how the bellows restraining device 18 can be used to determine how the bellows restraining device 18 is designed and how it interacts with the bellows restraining device 18, Compression, and deflection, as well as preventing over-stress, compression, and deflection.

In Fig. 3A, the bellows 16 is in a stretched state to the point where the bellows restraining device 18 prevents excessive stress. In the stretched state, the bellows 16 is longer than the length of the bellows 16 in its free state. The reason for the extension of the bellows 16 is that the first standoff 26 and each shaft 50 of the second standoff are connected to the first through hole 44 and the second through hole 46 It does not touch anything. Therefore, the bellows 16 can increase the range of the flow until the shaft 50 contacts the surfaces of the first through-hole 44 and the second through-hole 46.

The extent to which the bellows 16 extends is equal to the distance between the shaft 50 of the first standoff 26 and the side of the first through hole 44 when the bellows restrictor 18 is free The distance between the shaft 50 of the second standoff 28 and the side of the first through hole 46 when the bellows restraining device 18 is free). If the bellows 16 is to be further elongated or compressed, the cross-section of the first through-hole 44 and the second through-hole 46 can be adjusted, by making the cross-section larger or smaller or making it elliptical or rectangular .

The cross section of the first through hole 44 may be different from the cross section of the second through hole 46. Another method of increasing or decreasing the flow range of the bellows 16 is expandable by adjusting the size of the cross section of each shaft 50 of the first and second standoffs 26 and 28 . In addition, with respect to the first standoff 26 and the second standoff 28, the arrangement of the first through hole 44 and the second through hole 46 along the female arm 42 is larger or smaller Can be adjusted to be stretchable.

3B, the bellows 16 is in a compressed state at a point where the bellows restraining device 18 is blocking further compression. In the compressed state, the bellows 16 is shorter than the length of the bellows 16 in the free state. The reason why the bellows 16 can be compressed is that the shafts 50 of the first standoff 26 and the second standoff 28 are free from the first through holes 44 and the second through holes 46). ≪ / RTI >

Therefore, the bellows 16 can be compressed in a range until the shaft 50 comes in contact with the side surfaces of the first through-hole 44 and the second through-hole 46. The range in which the bellows 16 can compress is the distance between the shaft 50 of the first standoff 26 and the side surface of the first through hole 44 when the bellows restrictor 18 is free, The distance between the shaft 50 of the second standoff 28 and the side surface of the second through hole 46 when the bellows restraining device 18 is in a free state).

If larger or smaller compression is required for the bellows 16, the cross-section of the first through-hole 44 and the second through-hole 46 can be adjusted, for example, It can be modified to be elliptical or triangular. The cross-section of the first through-hole 44 may be different from that of the second through-hole 46. Another way to increase or decrease the amount by which the bellows 16 can be compressed is to adjust the size of the cross sectional area of each shaft 50 of the first standoff 26 and the second standoff 28, .

The arrangement of the first through hole 44 and the second through hole 46 along the female arm 42 with respect to the first standoff 26 and the second standoff 280 becomes larger or smaller . ≪ / RTI >

 3C, the bellows 16 is in a first deflected state (deflected downward in FIG. 3C) to a point where the bellows restraining device 18 prevents any other angular deflection. When the deflected state or the bellows 16 is deflected in the plane parallel to the male arm 32 and the female arm 42 (i.e., deflected upward in Fig. 3C), the first standoff 26 and the second standoff 26 2 Each shaft 50 of the standoff 28 contacts the first through hole 44 and the second through hole 46 in the vicinity of the upper side or the lower side, respectively. The reason why the bellows 16 is allowed to deflect in a plane parallel to the male arm 32 and the female arm 42 is that the free ends of the first standoff 26 and the second standoff 28, 50 are not in contact with either of the first through holes 44 and the second through holes 46, respectively. Therefore, the bellows 16 can deflect the amount until the shaft 50 comes in contact with the surfaces of the first through-hole 44 and the second through-hole 46.

It is possible to adjust the cross section of the first through hole 44 and the second through hole 46 when a larger or smaller deflection is required on the surface parallel to the male arm 32 and the female arm 42 in the bellows 16. [ For example, the cross section can be made larger or smaller circles, or can be modified to be elliptical or triangular. The cross-section of the first through-hole 44 may be different from that of the second through-hole 46. Another way to increase or decrease the extent to which the bellows 16 can be deflected in a plane parallel to the water hammer 32 and the female arm 42 is to move the first standoff 26 and the second standoff 28 To adjust the size or shape of the cross-sectional area of each shaft 50 (described with reference to Figs. 7 and 8).

In Figure 3D, the bellows 16 is in a second biased state (downward in Figure 3d) to the point where the bellows restraint 18 prevents any other angular deflection. When the deflected state or the bellows 16 is deflected vertically with respect to the water hammer 32 and the female arm 42 (i.e., deflected upward in Fig. 3D), the first standoff 26 and the second stand < Each of the shafts 50 of the first through hole 28 is in contact with the side end of each of the first through hole 44 and the second through hole 46 and the end of the male arm 32 is in contact with the And the head 48 of the second standoff 28 is in contact with the side surface of the female arm 42.

When the bellows 16 is deflected in the opposite direction (that is, in the downward direction in Fig. 3D), each shaft 50 of the first standoff 26 and the second standoff 28 is connected to the first through hole 44 And the female arm 42 contacts the end of the male mount 24 and the head 48 of the first standoff 26 contacts the end of the second standoff 26 The side surface of the female arm 42 comes into contact.

The reason why the bellows 16 is allowed to be angularly deflected perpendicular to the water hammer 32 and the female arm 42 is that the first standoff 26 and the second standoff 28, There is a gap between the male arm 3 and the female arm 42 without the first through hole 44 and the second through hole 46 being in contact with any surface of the first through hole 44 and the second through hole 46, Because each head 48 of the first standoff 26 and the second standoff 28 is spaced apart from the surface of the female arm 42 (as shown in FIG. 2B). Therefore, the bellows 16 remains in contact with the female arm 42 until the first standoff 26 and the second standoff 28 come into contact / contact with the female arm 42 or until the male arm 32 contacts the female arm 42 It can be deflected to the flow range.

If larger or smaller deflections are needed in the bellows 16 perpendicular to the male and female arms 32 and 42, many dimensions can be changed. The cross section of the first through hole 44 and the second through hole 46 can be adjusted. For example, the cross section can be made into a circle having a larger or smaller cross section, or an ellipse or a triangle. The cross-section of the first through-hole 44 may be different in size or shape from the cross-section of the second through-hole 46. Another way to increase or decrease the extent to which the bellows 16 can be deflected is to adjust the size of the cross sectional area of each shaft 50 of the first standoff 26 and the second standoff 28, Or by increasing or decreasing the thickness of the female arm 42. Increasing or decreasing the length of the shaft 50 may also increase or decrease the distance between the male arm 32 and the female arm 42 or increase or decrease the distance between the female arm 42 and the first standoff 26 and second Allows for greater or lesser deflection by lengthening or reducing the space between each head 48 of the standoffs 28. Finally, the arrangement of the male arm 32 and / or the female arm 42 with respect to the male mount 30 and the female mount 40 can be adjusted by adjusting the distance between the male arm 32 and the female arm 42 Allows larger or smaller deflection.

With regard to the deflection of the bellows 16 which is not in the plane parallel to the water hammer 32 and the female arm 42 or in the vertical plane, the contact between the components of the bellows restrictor 16 is shown in Figures 3c and 3d And the adjustments made to increase or decrease the deflection of the bellows 16 in this direction would be a combination of the adjustments described in connection with Figures 3C and 3D.

7 is a measurement view of another embodiment of a standoff for use with the bellows restraint device 18 in the first deflection state. The bellows restraining device 18 of Figure 7 is configured such that the cross sectional area of each shaft 150 of the first standoff 126 and the second standoff 128 is greater than the cross sectional area of the first standoff 26 and the second standoff 28 Is greater than the cross-sectional area of each shaft (50). There is less space between the shaft 150 and each of the first through holes 44 and the second through holes 46 when the bellows restraining device 18 is in the free state because the shaft 150 has a larger cross- do. Therefore, the bellows 16 is deflected only a small amount until the shaft 150 comes into contact with the side surfaces of each of the first through holes 44 and the second through holes 46. In FIGS. 2C, 7 and 8, the range of deviation of the allowed deflection in each embodiment is indicated by comparing the range of deflection with the centerline CL. The first standoff 126 and the second standoff 128 with the larger diameter shaft 150 also allow less deflection in different directions than shafts with smaller diameters.

8 is a measurement view of a third embodiment of the standoff used with the bellows restraint device 18 in the first deflection state. The bellows restraining device 18 of Figure 8 is configured such that the cross sectional area of each shaft 250 of the first standoff 226 and the second standoff 228 is greater than the cross sectional area of the first standoff 26 and the second standoff 28 7 is the same as the bellows restraining device 18 of the previous drawings, including Fig. 7, except that the cross-sectional area of each shaft 50 is smaller than that of each shaft 50. Fig. There is more space between the shaft 250 and each of the first through holes 44 and the second through holes 46 when the bellows restrictor 18 is in the free state because the shaft 250 has a smaller cross- do. Therefore, the bellows 16 is biased to a large extent until the shaft 250 contacts the side surfaces of the first through holes 44 and the second through holes 46. [ The first standoff 226 and the second standoff 228, which have a smaller diameter shaft 250, also allow more deflection (greater deflection) in different directions than shafts with larger diameters.

Other embodiments of standoffs of the bellows restraint device 18 may be mutually interchangeable such that each standoff may be provided with a different standoff having a larger or smaller cross-sectional area, e.g., the first standoff 126 of FIG. 7 The deflection range can be adjusted by replacing the second standoff 128 or the first standoff 226 and the second standoff 228 in Fig. Since the first standoffs 26, 126, 226 and the second standoffs 28, 128, 228 can be attached to the male arm 32 using a screw connection, the replacement of the standoff is quick and easy. Compression and angular deflection of the bellows 16 may therefore be adjusted in accordance with design considerations and changes to the hydraulic system 10 even after application of the bellows restraint 18 adjacent the bellows 16. [

9 is a perspective view of a fourth embodiment of the bellows-restraining device 318 in a free state. The hydraulic system 10 of Figure 9 is identical to the hydraulic system 10 from the previous figures except for the bellows constraining device 318 (as opposed to the bellows constraining device 318 from the previous figures). Figure 9 shows a portion of the tube 14 and the bellows 16. The bellows restraining device 318 includes a male bracket 332, an arm bracket 324, a first standoff 326 and a second standoff 328. The male bracket 322 includes a male mount 330 having an upper male mount 330a and a lower male mount 330b and a male arm 332 having a first connector 334 and a second connector 336 . The arm bracket 324 includes an arm mount 340 having an upper arm mount 340a and a lower arm mount 340b and a female arm 342 having a first through hole 344 and a second through hole 346 .

The configuration of the bellows restraining device 318 is such that the male and female mounts 330 and 340 are connected to the upper mounts 330a and 340a and the lower mounts 330a and 330b, (Lower arm mount 340b), respectively, of the bellows restraining device 18, respectively. Separating the mount into several pieces allows each of the mounts to be installed and detached from the surrounding tube after the hydraulic system 10 has already been assembled without the need to disassemble the tube 14 and the bellows 16. [ The upper water mount 330a and the upper arm mount 340a may be attached to the lower water mount 330b and the lower arm mount 340b by various means such as a rivet, a clamp, a screw connection having bolts 352 shown in FIG. 9, It can be assembled by other means.

The upper water mount 330a and lower water mount 330b may be configured to rigidly surround the tube 14 such that the water mount 330 and the male bracket 322 are not rotated about the tube 14, The mount 330 may be configured to rotate relative to the tube 14. The upper and lower arm mounts 340a and 340b are configured to securely surround the tube 14 such that the arm mount 340 and the arm bracket 324 are not rotated about the tube 14 Or the arm mount 340 may be configured to rotate relative to the tube 14. However, the configuration of the male mount 330 and the arm mount 340 should be such that they can be easily installed and separated without damaging the tube 14 and the bellows 16 without the need to separate the hydraulic system 10 . Although the upper water mount 330a, the upper arm mount 340a, the lower water mount 330b and the lower arm mount 340b are shown as having flanges for receiving the fasteners 454, Lt; RTI ID = 0.0 > of the < / RTI >

A bellows restrictor 18 and 318 for use with the bellows 16 are disclosed herein and include a plurality of bellows 16 extending therethrough at opposite ends of the bellows 16 to limit elongation, Includes a bracket (22) and an arm bracket (24). The bellows 16 may be located along the tube 14 through which the fluid flows, such as in the hydraulic system 10. The male bracket 22 has a male mount 30 attached to the tube 14 near the bellows 16 and a male arm 32 extending radially outwardly adjacent the bellows 16. [ The arm bracket 24 includes a female arm 40 attached to the tube 14 at the other end of the bellows 16 and a female arm 24 extending radially outwardly from the bellows 16 adjacent the male arm 32 42). The bellows-restraining device 18 extends through the corresponding through-holes (the first through-hole 44 and the second through-hole 46) of the female type arm 42 so as to be located at a position corresponding to the male arm 32 (The first standoff 26 and the second standoff 28) connected at the second connector 36 (the connector 34 and the second connector 36). The standoffs and through-holes are sized so that the bellows 16 is elongated, compressed and angularly biased in a certain range and then the standoff is brought into contact with the female arm 42 (through the first through hole 44 and the second through- Thereby preventing the bellows 16 from overflowing.

The disclosed bellows restraining devices 18 and 318 have many advantages. The bellows constraining devices 18 and 318 may also be used when the bellows 16 and the tube 14 are coated with a corrosion-resistant coating. If a coating is used, the bellows 16 can stretch, compress and deflect only a certain amount before coating cracking, so that the bellows constraining devices 18 and 318 prevent coating damage. The bellows constraining devices 18 and 318 prevent damage to the bellows 16 due to over-stress, compression and over-deflection, thereby increasing the life of the bellows 16. [ The bellows 18 and 318 can be configured to constrain the bellows 16 by a constant flow range. For example, one bellows restraining device 18 can be designed to move 5% in all directions while another bellows restraining device 18 can be designed to be 10% angular deflection and 7% stretching and compression .

The bellows constraining devices 18 and 318 are simple and require only two attachment points (male and female mounts 30 and 40) and a limited number of separate components. As described above, the bellows restraining devices 18 and 318 can be easily adjusted to provide greater or lesser force by replacing the first standoff 26 and / or the second standoff 28 with another standoff A standoff having a larger or smaller diameter; For example a first standoff 126 or 226 and a second standoff 128 or 228; A standoff having a non-circular cross-section; For example, elliptical, rectangular, triangular or other shapes; Or standoffs of longer or shorter length.

The arm bracket 24 can also be replaced with another arm bracket 24 having a female arm 42 with a first through hole 44 and / or a second through hole 46 of different sizes, This permits larger or smaller movements of the second standoff 28 within the range of the first standoff 26 and the second throughhole 46 within the range of the first throughhole 44. Another advantage is that the bellows restraining device 18 is smaller in size than the prior art bellows restraining devices because it has a cylindrical tube 18 surrounding the bellows with rods extending parallel to the bellows on each side to prevent extensive flow of the bellows. The bellows restraining device 18 has a male arm 32 and a female arm 42 extending only along one side of the bellows 16 to still restrict movement of the bellows 16 in all directions will be. The bellows constraining devices 18 and 318 are applicable to an existing bellows 16 without the need to modify or replace the bellows 16. [ Thus, the bellows constraining device 318 can be configured to allow installation and disassembly without the need to disassemble the tube 14 and bellows 16 of the hydraulic system 10. [

As used herein, the terms relative terms or degrees, such as "substantially," "essentially," "generally," "roughly," and similar terms may be used interchangeably with any application Possible relative terms or degrees of terminology used herein should be interpreted relative to the disclosed embodiments in view of the entirety of this specification, Such as, for example, encompassing general manufacturing tolerance variations, minor alignment changes, alignment or shape changes induced by thermal, rotational, or vibratory operating conditions, and the like .

While the present invention has been described with reference to exemplary embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Accordingly, it is not intended that the invention be limited to the particular embodiment (s) disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims (20)

A first bracket having a first mount and a first arm extending from the first mount;
A second bracket having a second mount and a second arm extending adjacent to the first arm from the second mount and having at least one through hole; And
A first fastener extending through the at least one through-hole of the second arm to be connected to the first arm; and the first fastener includes a first fastener extending through the at least one through- Sectional area smaller than the cross-sectional area of the through-hole of the bellows. The method according to claim 1,
Wherein the at least one through hole includes a first through hole corresponding to the first fastener and a second through hole having a same direction as the first through hole,
A second fastener extending through the second through-hole of the second arm so as to be connected to the first arm, and the second fastener being connected to the second arm so as to move the first bracket in relation to the second bracket, Sectional area smaller than the cross-sectional area of the bore. The method according to claim 1,
Wherein the cross-sectional area of the at least one through hole is circular and the cross-sectional area of the first fastener is circular. The method according to claim 1,
And the cross-sectional area of the first fastener is elliptical. The method according to claim 1,
And a gap is present between the first arm and the second arm. The method according to claim 1,
And a gap is present between the first arm and the second arm. The method according to claim 1,
And a head for preventing the first fastener from being pushed through the at least one through hole. A tube having a hollow inner flow passage configured to allow fluid to flow through the tube, an expansion joint present along the tube, and a male mount abutting the tube and a male arm extending adjacent to the expansion joint, ;
An arm bracket including an arm mount and an expansion joint abutting the tube and a female arm extending adjacent to the male arm and having at least one through hole;
And a first standoff extending through the at least one through-hole of the female arm and coupled to the male arm configured to limit elongation, compression and angular deflection of the expansion joint. 9. The method of claim 8,
Wherein the hollow inner flow path is coated with a corrosion-resistant coating. 9. The method of claim 8,
The male mount is annular in shape and surrounds the tube at a first point adjacent one end of the expansion joint and the arm mount is annular in shape and surrounds the tube at a second point adjacent the opposite end of the expansion joint. 9. The method of claim 8,
Wherein the male arm is substantially rectangular with a length similar to the length of the expansion joint and the female arm is substantially similar in length to the length of the expansion joint. 9. The method of claim 8,
Wherein the at least one through hole includes a first through hole corresponding to the first standoff and a second through hole along the length of the female arm,
And a second standoff extending through the second through-hole of the female arm and fastened to the female arm. 13. The method of claim 12,
Wherein the first standoff has a cross sectional area smaller than the cross sectional area of the first through hole and the second standoff has a cross sectional area smaller than the cross sectional area of the second through hole. 13. The method of claim 12,
Wherein the first standoff comprises a first head and the second standoff comprises a second head to prevent the male bracket from detaching from the arm bracket. 13. The method of claim 12,
Wherein the first standoff has a circular cross-section and the second standoff has a circular cross-section. 13. The method of claim 12,
Wherein the first standoff has an elliptical cross-section and the second standoff has an elliptical cross-section. 9. The method of claim 8,
Wherein the male bracket and the female bracket are configured such that a gap exists between the male and female arms when the expansion joint is in a free state. 9. The method of claim 8,
Wherein the male bracket and the female bracket are configured such that a gap exists between the male and female arms when the expansion joint is in a free state. 9. The method of claim 8,
Said tube transferring hydraulic fluid. Fluid lines;
A bellows along a fluid line configured to allow compression, extension and angular deflection of the fluid line; And
A bellows constraining device adjacent the bellows configured to limit the flow range of compression, extension and angular deflection of the fluid line;
The first support having a first bellows attachment portion connecting a first support to the first end of the bellows and a first extension extending along the fluid line adjacent the bellows,
The second support has a second bellows attachment, a second extension, a first opening and a second opening, the second attachment connects the second support of the bellows to the second end of the bellows, Extending along a fluid line adjacent the first extension,
Wherein the first standoff has a first shaft and a first head, the first shaft extends through the first opening in the first extension and the first shaft has a cross-sectional area smaller than the cross-sectional area of the first opening,
Wherein the second standoff has a second shaft and a second head, the second shaft extends through the second opening in the second extension and is connected to the first extension and the second shaft is connected to the second opening And a bellows-restraining device having a cross-sectional area smaller than the cross-sectional area of the bellows-restraining device.

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